Influence of a damage zone on high temperature crack growth in brittle materials

D.B. Sabljic, D.S. Wilkinson
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引用次数: 4

Abstract

High temperature crack growth in ceramics often occurs by the nucleation, growth and coalescence of cavities in a region ahead of the crack tip known as the damage zone. Models describing this type of behaviour generally assume that the presence of cavities does not affect the stress distribution ahead of the crack tip. In this study, a crack growth simulation has been developed which incorporates the effects of cavity nucleation, growth and coalescence on the stress field ahead of the crack. Cavity growth dominated both by grain boundary diffusion and by surface diffusion has been modelled. The models follow both the transient effects which occur following initial loading and the development of a steady-state regime under conditions of constant applied stress intensity factor KI. In general, the wedging action due to cavity growth reduces the stress field near the crack tip. However, this is largely compensated for by an increase in the damage zone size, as a result of load transfer from the crack tip to the end of the damage zone. We have therefore demonstrated that the established analytical models which do not account for stress redistribution give a much better description of steady-state crack growth behavior than one would expect.

损伤区对脆性材料高温裂纹扩展的影响
陶瓷中的高温裂纹扩展通常是由裂纹尖端前面称为损伤区的空腔的形核、生长和聚并引起的。描述这种行为的模型通常假设空腔的存在不影响裂纹尖端前的应力分布。在这项研究中,建立了一个裂纹扩展模拟,该模拟考虑了空洞形核、扩展和合并对裂纹前方应力场的影响。模拟了由晶界扩散和表面扩散主导的空腔生长。这些模型既遵循初始加载后的瞬态效应,也遵循恒定施加应力强度因子KI条件下的稳态状态。一般来说,由于空腔生长而产生的楔入作用减小了裂纹尖端附近的应力场。然而,由于载荷从裂纹尖端转移到损伤区末端,这在很大程度上被损伤区尺寸的增加所补偿。因此,我们已经证明,建立的不考虑应力再分布的分析模型对稳态裂纹扩展行为的描述比人们预期的要好得多。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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